Solution NMR structures reveal a distinct architecture and provide first structures for protein domain family PF04536

The protein family (Pfam) PF04536 is a broadly conserved domain family of unknown function (DUF477), with more than 1,350 members in prokaryotic and eukaryotic proteins. High-quality NMR structures of the N-terminal domain comprising residues 41–180 of the 684-residue protein CG2496 from Corynebacterium glutamicum and the N-terminal domain comprising residues 35–182 of the 435-residue protein PG0361 from Porphyromonas gingivalis both exhibit an α/β fold comprised of a four-stranded β-sheet, three α-helices packed against one side of the sheet, and a fourth α-helix attached to the other side. In spite of low sequence similarity (18%) assessed by structure-based sequence alignment, the two structures are globally quite similar. However, moderate structural differences are observed for the relative orientation of two of the four helices. Comparison with known protein structures reveals that the α/β architecture of CG2496(41–180) and PG0361(35–182) has previously not been characterized. Moreover, calculation of surface charge potential and identification of surface clefts indicate that the two domains very likely have different functions.     

Solution NMR structure of Alr2454 from Nostoc sp. PCC 7120, the first structural representative of Pfam domain family PF11267

Protein domain family PF11267 (DUF3067) is a family of proteins of unknown function found in both bacteria and eukaryotes. Here we present the solution NMR structure of the 102-residue Alr2454 protein from Nostoc sp. PCC 7120, which constitutes the first structural representative from this conserved protein domain family. The structure of Nostoc sp. Alr2454 adopts a novel protein fold.     

Solution NMR structures of immunoglobulin-like domains 7 and 12 from obscurin-like protein 1 contribute to the structural coverage of the human cancer protein interaction network

High-quality solution NMR structures of immunoglobulin-like domains 7 and 12 from human obscurin-like protein 1 were solved. The two domains share 30 % sequence identity and their structures are, as expected, rather similar. The new structures contribute to structural coverage of human cancer associated proteins. Mutations of Arg 812 in domain 7 cause the rare 3-M syndrome, and this site is located in a surface area predicted to be involved in protein–protein interactions.     

Solution NMR structures of the C‐domain of Tetrahymena cytoskeletal protein Tcb2 reveal distinct calcium‐induced structural rearrangements

Tcb2 is a calcium‐binding protein that localizes to the membrane‐associated skeleton of the ciliated protozoan Tetrahymena thermophila with hypothesized roles in ciliary movement, cell cortex signaling, and pronuclear exchange. Tcb2 has also been implicated in a unique calcium‐triggered, ATP‐independent type of contractility exhibited by filamentous networks isolated from the Tetrahymena cytoskeleton. To gain insight into Tcb2's structure‐function relationship and contractile properties, we determined solution NMR structures of its C‐terminal domain in the calcium‐free and calcium‐bound states. The overall architecture is similar to other calcium‐binding proteins, with paired EF‐hand calcium‐binding motifs. Comparison of the two structures reveals that Tcb2‐C's calcium‐induced conformational transition differs from the prototypical calcium sensor calmodulin, suggesting that the two proteins play distinct functional roles in Tetrahymena and likely have different mechanisms of target recognition. Future studies of the full‐length protein and the identification of Tcb2 cellular targets will help establish the molecular basis of Tcb2 function and its unique contractile properties. Proteins 2016; 84:1748–1756. © 2016 Wiley Periodicals, Inc.     

Chlorophylls of the c family: absolute configuration and inhibition of NADPH:protochlorophyllide oxidoreductase

Using circular dichroism (CD) spectroscopy, the stereochemistry at C-13(2) of members of the chlorophyll (Chl) c family, namely Chls c(1), c(2), c(3) and [8-vinyl]-protochlorophyllide a (Pchlide a) was determined. By comparison with spectra of known enantiomers, all Chl c members turned out to have the (R) configuration, which is in agreement with considerations drawn from chlorophyll biosynthesis. Except for a double bond in the side chain at C-17, the chemical structure of Chl c(1) is identical with Pchlide a, the natural substrate of the light-dependent NADPH:protochlorophyllide oxidoreductase (POR). Thus, lack of binding to the active site due to the wrong configuration at C-13(2), which had been proposed previously, cannot be an explanation for inactivity of Chl c in this enzymic reaction. Our results show rather that Chl c(1) is a competitive inhibitor for this enzyme, tested with Pchlide a and Zn-protopheophorbide a (Zn-Ppheide a) as substrates.     

NMR structure of the Bordetella bronchiseptica protein NP_888769.1 establishes a new phage-related protein family PF13554

The solution structure of the hypothetical phage-related protein NP_888769.1 from the Gram-negative bacterium Bordetella bronchoseptica contains a well-structured core comprising a five-stranded, antiparallel β-sheet packed on one side against two α-helices and a short β-hairpin with three flexibly disordered loops extending from the central β-sheet. A homology search with the software DALI identified two Protein Data Bank deposits with Z-scores > 8, where both of these proteins have less than 8% sequence identity relative to NP_888769.1, and one has been functionally annotated as a lambda phage tail terminator protein. A sequence-homology analysis then confirmed that NP_888769.1 represents the first three-dimensional structural representative of a new protein family that was previously predicted by the Joint Center for Structural Genomics, which includes so far about 20 prophage proteins encoded in bacterial genomes.     

Three structural representatives of the PF06855 protein domain family from Staphyloccocus aureus and Bacillus subtilis have SAM domain-like folds and different functions

Protein domain family PF06855 (DUF1250) is a family of small domains of unknown function found only in bacteria, and mostly in the order Bacillales and Lactobacillales. Here we describe the solution NMR or X-ray crystal structures of three representatives of this domain family, MW0776 and MW1311 from Staphyloccocus aureus and yozE from Bacillus subtilis. All three proteins adopt a four-helix motif similar to sterile alpha motif (SAM) domains. Phylogenetic analysis classifies MW1311 and yozE as functionally equivalent proteins of the UPF0346 family of unknown function, but excludes MW0776, which likely has a different biological function. Our structural characterization of the three domains supports this separation of function. The structures of MW0776, MW1311, and yozE constitute the first structural representatives from this protein domain family.     

NMR and small-angle scattering-based structural analysis of protein complexes in solution

Structural analysis of multi-domain protein complexes is a key challenge in current biology and a prerequisite for understanding the molecular basis of essential cellular processes. The use of solution techniques is important for characterizing the quaternary arrangements and dynamics of domains and subunits of these complexes. In this respect solution NMR is the only technique that allows atomic- or residue-resolution structure determination and investigation of dynamic properties of multi-domain proteins and their complexes. As experimental NMR data for large protein complexes are sparse, it is advantageous to combine these data with additional information from other solution techniques. Here, the utility and computational approaches of combining solution state NMR with small-angle X-ray and Neutron scattering (SAXS/SANS) experiments for structural analysis of large protein complexes is reviewed. Recent progress in experimental and computational approaches of combining NMR and SAS are discussed and illustrated with recent examples from the literature. The complementary aspects of combining NMR and SAS data for studying multi-domain proteins, i.e. where weakly interacting domains are connected by flexible linkers, are illustrated with the structural analysis of the tandem RNA recognition motif (RRM) domains (RRM1-RRM2) of the human splicing factor U2AF65 bound to a nine-uridine (U9) RNA oligonucleotide.     

Optimization and validation of multi-state NMR protein structures using structural correlations

Journal of Biomolecular NMR - Recent advances in the field of protein structure determination using liquid-state NMR enable the elucidation of multi-state protein conformations that can provide...     

Mapping the protein domain structures of the respiratory mucins: a mucin proteome coverage study

Mucin genes encode a family of the largest expressed proteins in the human genome. The proteins are highly substituted with O-linked oligosaccharides that greatly restrict access to the peptide backbones. The genomic organization of the N-terminal, O-glycosylated, and C-terminal regions of most of the mucins has been established and is available in the sequence databases. However, much less is known about the fate of their exposed protein regions after translation and secretion, and to date, detailed proteomic studies complementary to the genomic studies are rather limited. Using mucins isolated from cultured human airway epithelial cell secretions, trypsin digestion, and mass spectrometry, we investigated the proteome coverage of the mucins responsible for the maintenance and protection of the airway epithelia. Excluding the heavily glycosylated mucin domains, up to 85% coverage of the N-terminal region of the gel-forming mucins MUC5B and MUC5AC was achieved, and up to 60% of the C-terminal regions were covered, suggesting that more N- and sparsely O-glycosylated regions as well as possible other modifications are available at the C-terminus. All possible peptides from the cysteine-rich regions that interrupt the heavily glycosylated mucin domains were identified. Interestingly, 43 cleavage sites from 10 different domains of MUC5B and MUC5AC were identified, which possessed a non-tryptic cleavage site on the N-terminal end of the peptide, indicating potential exposure to proteolytic and/or spontaneous cleavages. Some of these non-tryptic cleavages may be important for proper maturation of the molecule, before and/or after secretion. Most of the peptides identified from MUC16 were from the SEA region. Surprisingly, three peptides were clearly identified from its heavily glycosylated regions. Up to 25% coverage of MUC4 was achieved covering seven different domains of the molecule. All peptides from the MUC1 cytoplasmic domain were detected along with the three non-tryptic cleavages in the region. Only one peptide was identified from MUC20, which led us to successful antisera raised against the molecule. Taken together, this report represents our current efforts to dissect the complexities of mucin macromolecules. Identification of regions accessible to proteolysis can help in the design of effective antibodies and points to regions that might be available for mucin-protein interactions and identification of cleavage sites will enable understanding of their pre- and post-secretory processing in normal and disease environments.     

Solution NMR and X-ray crystal structures of membrane-associated Lipoprotein-17 domain reveal a novel fold

The conserved Lipoprotein-17 domain of membrane-associated protein Q9PRA0_UREPA from Ureaplasma parvum was selected for structure determination by the Northeast Structural Genomics Consortium, as part of the Protein Structure Initiative's program on structure-function analysis of protein domains from large domain sequence families lacking structural representatives. The 100-residue Lipoprotein-17 domain is a "domain of unknown function" (DUF) that is a member of Pfam protein family PF04200, a large domain family for which no members have characterized biochemical functions. The three-dimensional structure of the Lipoprotein-17 domain of protein Q9PRA0_UREPA was determined by both solution NMR and by X-ray crystallography at 2.5 ?. The two structures are in good agreement with each other. The domain structure features three α-helices, α1 through α3, and five β-strands. Strands β1/β2, β3/β4, β4/β5 are anti-parallel to each other. Strands β1and β2 are orthogonal to strands β3, β4, β5, while helix α3 is formed between the strands β3 and β4. One-turn helix α2 is formed between the strands β1 and β2, while helix α1 occurs in the N-terminal polypeptide segment. Searches of the Protein Data Bank do not identify any other protein with significant structural similarity to Lipoprotein-17 domain of Q9PRA0_UREPA, indicating that it is a novel protein fold.